|Home | About | Journals | Submit | Contact Us | Français|
The multistep sequence leading to leukocyte migration is thought to be locally regulated at the inflammatory site. Here, we show that broad systemic programs involving long-range signals from the sympathetic nervous system (SNS) delivered by adrenergic nerves, regulate rhythmic recruitment of leukocytes in tissues. Constitutive leukocyte adhesion and migration in murine bone marrow (BM) and skeletal muscle microvasculature fluctuated with circadian peak values at night. Migratory oscillations, altered by experimental jetlag, were implemented by perivascular SNS fibers, acting on β-adrenoreceptors expressed on non-hematopoietic cells, and leading to tissue-specific, differential circadian oscillations in the expression of endothelial cell adhesion molecules and chemokines. We showed that these rhythms have physiological consequences by alteration of hematopoietic cell recruitment and overall survival in models of septic shock, sickle cell vaso-occlusion and BM transplantation. These data provide unique insight in the leukocyte adhesion cascade and the potential for time-based therapeutics for transplantation and inflammatory diseases.
Leukocyte recruitment is critical for combating pathogens in the periphery as well as for bone marrow (BM) repopulation after transplantation. Much progress has been made in the past two decades in our understanding of the major molecular mechanisms involved in leukocyte recruitment in response to an inflammatory challenge. Leukocytes initially tether and roll on endothelial cell P- and E-selectins, allowing signals from chemokines and endothelial receptors to activate leukocyte integrins to bind to intercellular cell adhesion molecule-1 (ICAM-1) and vascular cell adhesion molecule-1 (VCAM-1). These high affinity interactions lead to leukocyte arrest on endothelial cells and subsequently diapedesis toward an inflammatory site or for engraftment in the BM (Butcher, 1991; Ley et al., 2007; Muller, 2011; Springer, 1994; Vestweber and Blanks, 1999; Wagner and Frenette, 2008). This sequential multistep process is regulated by signals in situ from adhesion receptors and by soluble factors (e.g. cytokines and chemoattractants), thereby enabling endothelial cells to serve as gatekeepers at the interface of blood and tissues.
While leukocyte migration in inflammatory scenarios has been intensely studied, the regulation of leukocyte trafficking under homeostasis is less understood. Steady-state migration of hematopoietic stem cells (HSCs) and lymphocytes in lymphoid and non-lymphoid tissues has been described as part of normal immunosurveillance to maximize encounters with potential pathogens (Massberg et al., 2007; Sigmundsdottir and Butcher, 2008; von Andrian and Mackay, 2000). It has been assumed that similar surveillance mechanisms exist for myeloid cells whose migration to tissues exposed to the external environment (e.g. skin, gut) keeps pathogens at bay. Constitutive, low level expression of endothelial adhesion molecules likely regulates myeloid cell trafficking because mice lacking major adhesion pathways are susceptible to spontaneous bacterial infections (Bullard et al., 1996; Forlow et al., 2002; Frenette et al., 1996). Since leukocytes play key roles in regenerative processes, one would predict that the organism also possesses broad “housekeeping” programs to maintain the integrity of all tissues, irrespective of infectious probabilities.
Circadian rhythms regulate several vital biological processes through internal molecular clocks (Dibner et al., 2010; Green et al., 2008). Blood leukocyte numbers have long been known to exhibit circadian oscillations (Haus and Smolensky, 1999) and more recent studies have revealed that the release of hematopoietic stem and progenitor cells from the BM follows similar rhythms (Lucas et al., 2008; Mendez-Ferrer et al., 2008). Interestingly, specific circadian times have been linked with the onset of acute diseases, notably in the cardio-vascular system (Muller et al., 1985; Willich et al., 1987). Emerging data, in turn, indicate that chronic perturbations of circadian rhythms promote vascular diseases (Anea et al., 2009; Brown et al., 2009). Although the mechanisms are still undefined, numerous studies have demonstrated strong associations between high leukocyte counts and various ischemic vascular diseases (Coller, 2005; Margolis et al., 2005). Here, we tested the hypothesis that circadian-controlled neural signals influence leukocyte behavior and the inflammatory response. We show that leukocyte recruitment to tissues under homeostasis was not a continuous process, but rather exhibited circadian oscillations, and that these rhythms, orchestrated by the molecular clock via adrenergic nerves, can impact disease outcome.
Bmal1−/− (gift from C. A. Bradfield), Adrb2tm1Bkk (gift from G. Karsenty), Berkeley SCD mice [Tg(Hu-miniLCRα1GγAγδβS) Hba−/− Hbb−/−] (gift from N. Mohandas), Sele−/−Selp−/−, FVB/N-Adrb3tm1Lowl/J, Icam1tm1Jcgr/J, Vav1-creA2Kio/J, STOCK Tg(TIE2GFP)287Sato/J mice (all from Jackson Laboratories), and ROSA26Sortm2(ACTB−Luc)Tyj and the inbred FVB/NJ and C57BL/6-CD45.1/2 congenic strains (all from the National Cancer Institute) were used in this study. See Extended Experimental Procedures for references and details. All mice used were males, housed on a 12h-light/dark cycle (lights on/off at 7am/7pm) with food ad libitum. All experimental procedures were approved by the Animal Care and Use Committees of Albert Einstein College of Medicine and Mount Sinai School of Medicine.
Details can be found in Extended Experimental Procedures.
Whole-mount immunostaining of cremaster muscle and BM tissues was performed as previously detailed (Scheiermann et al., 2007). See Extended Experimental Procedures for details.
BIM determination of leukocyte/vessel wall interactions in murine cremasteric venules, hemodynamic characteristics, and image analyses were studied as previously detailed (Chang et al., 2008; Scheiermann et al., 2009). For MFIM, animals were prepared as previously detailed for the cremaster (Chiang et al., 2007) and the BM (Mazo et al., 1998). See Extended Experimental Procedures for details.
The genitofemoral nerve (Lucio et al., 2001) and the superior cervical ganglion (Alito et al., 1987; Walton and Buono, 2003) were dissected as described. See Extended Experimental Procedures for details.
Transplantation procedures were carried out using congenic CD45.1/2 mice. Chimeric mice were generated by i.v. injection of 1×106 donor mice bone marrow nucleated cells into lethally irradiated (12 Gy, split dose, 3h apart) mice as previously detailed (Katayama et al., 2006). For survival studies, the recovery of donor mature WBC in peripheral blood and survival were monitored as indicated. In some experiments, recipient mice were irradiated with 4 Gy of sublethal irradiation and donor/recipient chimerism in mature peripheral leukocytes were analyzed by flow cytometry.
Tissues were harvested from Tie2-GFP animals, minced and digested in type IV collagenase (Clostridium histolyticum, Sigma). Single cell suspensions were stained with DAPI and fluorescence-conjugated antibodies and analyzed by flow cytometry using an LSRII (BD). Data were analyzed with FlowJo (Tree Star) or FACS Diva 6.1 software. Endothelial cells were sorted into Q-PCR Dynabead lysis buffer (Invitrogen) and processed with SYBR green as previously described (Mendez-Ferrer et al., 2008). Details can be found in Extended Experimental Procedures.
BM cells were labeled with carboxyfluorescein succinimidyl ester (CFSE) (Invitrogen) as per manufacturer’s instructions and injected into non-irradiated recipient mice (at ZT4 and ZT12). Cells were allowed to circulate for 1h. The trafficking of labeled BM cells was assessed by MFIM of the BM immediately after 10µg of R6G was injected to visualize BM sinusoids. In some experiments, BM cells were labeled with VT680 (Visen MEDICAL). The subsets of adoptively transferred cells in the recipient BM were analyzed by flow cytometry.
Experiments were performed as previously described (Katayama et al., 2003). See Extended Experimental Procedures for details.
Isoproterenol, the β3 adrenergic agonist, BRL37344, or the β2 adrenergic agonist, clenbuterol (5 mg/kg) were injected i.p. for 5 days and an in vitro homing assay or BM transplantation was performed 24 hours after the last injection to minimize the direct effect of the drugs on the injected donor cells.
Details can be found in Extended Experimental Procedures.
To induce changes in light regime mice were placed in a light cycler (Park Bioservices) with a 12h-inverted light cycle for 12h (to induce jetlag), a minimum of 2 weeks to completely establish an inverse light cycle or kept for 3 weeks in complete darkness.
Details can be found in Extended Experimental Procedures.
All data are represented as mean ± SEM. Comparisons between two samples were done using the paired and unpaired Student’s t tests. One-way ANOVA analyses followed by Tukey’s multiple comparison tests were used for multiple group comparisons. Statistical analyses were performed with Graph Pad Prism 5. Log-rank analyses were used for Kaplan-Meier survival curves. *P<0.05, **P<0.01, ***P<0.001.
Circulating total leukocyte counts oscillate in murine blood, peaking ~5 h after the onset of light (zeitgeber time, ZT5) and exhibiting a trough at ZT13 (Figure 1A), confirming previous reports (Haus and Smolensky, 1999). These rhythms are observed for HSCs (Mendez-Ferrer et al., 2008) as well as all major leukocyte subsets (Figure S1A) but not erythrocytes and platelets (not shown).
To test whether the recruitment of leukocytes from the blood to tissues also exhibited circadian preferences, we initially investigated hematopoietic cell recruitment to the BM. When we assessed the recruitment potential of adoptively transferred BM cells throughout the day, we observed significant circadian oscillations in homing of total hematopoietic cells to the BM whose pattern ran in antiphase with that of blood exhibiting a peak at ZT13 and a trough in the daytime (ZT5) (Figure 1A). Circadian recruitment was observed for Lineage− Sca-1+ c-kit+ (LSK) cells (Figure 1B), colony-forming units in culture (CFU-C, Figure 1C), as well as neutrophils (Figure 1D).
To investigate the sequence of events in vivo, we visualized the interactions between circulating leukocytes and BM sinusoidal endothelium using multichannel fluorescence intravital microscopy (MFIM) of the calvarial BM as previously described (Chiang et al., 2007; Mazo et al., 1998). The number of endogenous rolling leukocytes in BM sinusoids was increased at ZT13 compared to ZT5 (Figure 1E and F) as was the number of adherent cells after adoptive transfer (Figure 1G–H and Figure S1B–C). These findings suggested that the circadian time has a significant impact on the rhythmic recruitment of different hematopoietic cell populations to the BM.
We next aimed to investigate whether circadian oscillations also dictated leukocyte recruitment to peripheral tissues using the cremasteric muscle as a model to investigate leukocyte-endothelial cell interactions in real time. Initial investigations by whole-mount immunofluorescence staining of unstimulated muscle tissues for the pan-leukocyte marker CD45 and myeloid antigens F4/80 or Gr-1, revealed numerous extravascular CD45+ cells alongside postcapillary venules identified by expression of platelet-endothelial cell adhesion molecule-1 (PECAM-1), vascular-endothelial cadherin (VE-Cadherin) and ephrin-receptor B4 (EphB4) (Figure 2A and S2A). Interestingly, extravascular leukocyte numbers exhibited circadian fluctuations, with CD45+F480+ macrophages representing the predominant leukocyte population in muscle (81% of CD45+ cells vs 2% for neutrophils, data not shown), peaking at ZT13 along postcapillary venules, where leukocyte infiltration mainly occurs (Figure 2B–C and S2B–C), but not arterioles or capillaries (Figure S2D). Staining for Ki67 revealed very few positive leukocytes with no detectable circadian rhythm (not shown) suggesting that the observed leukocyte increase at night was not due to proliferation.
We next quantified leukocyte recruitment in real-time in the exteriorized cremaster muscle by MFIM after injection of very low doses of fluorescently-conjugated antibodies to identify leukocyte populations in vivo (Figure 2D) (Chiang et al., 2007). Under surgically induced trauma conditions, the numbers of adherent neutrophils and monocytes significantly increased at night, while lymphocyte numbers remained unchanged (Figure 2E–G) and overall leukocyte rolling was not affected (not shown). No circadian differences in hemodynamic parameters such as blood flow or wall shear rates were observed at both time points in BM or skeletal muscle (Table S1). Thus, even when an inflammatory response is triggered, the experimental time can influence the recruitment of myeloid cells in trauma-stimulated tissues. Together, these data argue for analogous mechanisms orchestrating circadian recruitment to BM and skeletal muscle across a wide range of hematopoietic lineages and differentiation stages.
The circadian differences in leukocyte rolling and/or adhesion in the BM and skeletal muscle suggest substantial diurnal changes in the ability of endothelial cells to recruit leukocytes. We used transgenic mice expressing GFP under the Tie-2 promoter (Tie2-Gfp) to isolate endothelial cells (Motoike et al., 2000). Whole-mount staining of cremaster muscle and BM tissues from Tie2-Gfp mice as well as flow cytometry of collagenase IV-digested tissues using antibodies directed against PECAM-1 and VE-Cadherin confirmed endothelial GFP expression (Figure S3A–D). We therefore sorted the CD45− VE-Cadherin+ PECAM-1+ GFP+ subset for quantitative PCR (Q-PCR) analyses (Figure S3C–D). Interestingly, we observed significant fluctuations in Icam1 expression in sorted cremasteric endothelial cells with peak and trough values overlapping with those of leukocyte recruitment (Figure 3A). By contrast, and consistent with the circadian differences observed in adhesion but not rolling in the muscle (Figure 2E–F and data not shown), there was no difference in the expression of endothelial selectins (Sele and Selp), Vcam1, Icam2 or Cd44 (Figure 3A and S3E). Immunofluorescence staining of frozen tissue sections corroborated these data at the protein level (Figure 3B and Figure S3F). We confirmed circadian fluctuations of ICAM-1 on the endothelial cell surface in vivo by quantifying the numbers of i.v. injected adherent green or red fluorescent microspheres coated with anti-ICAM-1 or isotype control antibodies using MFIM (Figure 3C, left). Oscillations were also seen in hematopoietic Icam1−/− radiation chimeras, excluding the potential contribution from ICAM-1-bearing blood leukocytes (Figure 3C, right). We also investigated circadian expression levels of chemokines known to be involved in myeloid cell trafficking in cremasteric endothelial cells by Q-PCR. We detected a clear circadian rhythm for Ccl2 (Figure 3D) but not for other chemokines tested, including Ccl3, Ccl5, Cxcl1, Cxcl2 and Cx3cl1 (Figure S3G). In contrast to the muscle, BM endothelial cells exhibited circadian differences in P-selectin, E-selectin and VCAM-1, but not ICAM-1 at both the RNA and protein levels (Figure 3E and S3H).
To investigate the functional relevance of ICAM-1 and CCL2 fluctuations in skeletal muscle we examined the numbers of extravasated leukocytes in Icam1−/− mice and mice deficient in the CCL2 receptor (Ccr2−/−) by whole-mount ex vivo immunofluorescence. Consistent with our expression results, no circadian rhythm was apparent, demonstrating the critical requirement of these molecules in this activity (Figure 3F).
To assess the functional relevance of fluctuations in adhesion molecule expression in BM, we examined the role of P- and E-selectins. MFIM of BM microvessels of Sele−/−Selp−/− mice revealed that in these mice circadian oscillations in leukocyte recruitment were ablated (Figure 3G). In stark contrast and in agreement with the expression data, circadian leukocyte recruitment to the BM was independent of ICAM-1 since Icam1−/− mice exhibited no alterations in circadian oscillations in the BM relative to WT animals (Figure S3I).
Taken together, these data demonstrate that tissue-specific expression of key promigratory factors fluctuates within endothelial cells of these tissues. Of importance, the differences in their molecular signature correlate with the oscillations observed in their respective functions, i.e. adhesion in the cremaster muscle (ICAM-1, CCL2) and both rolling and adhesion in the BM (endothelial selectins, VCAM-1).
Most prior studies have focused on the relevance of humoral factors in synchronizing circadian rhythms (Dimitrov et al., 2009; Haus, 2007). We have recently described a key role for local innervation in the circadian release of HSCs from the BM (Mendez-Ferrer et al., 2008). To assess the function of local innervation in hematopoietic cell recruitment to tissues, we adopted two surgical approaches to denervate the cremaster muscle and BM. For the cremaster muscle, we denervated mice unilaterally by microsection of the genitofemoral nerve (GFNx) (Lucio et al., 2001) that innervates this tissue (Zempoalteca et al., 2002). For the BM, we sympathectomized mice by unilateral surgical ablation of the superior cervical ganglion (SCGx) (Alito et al., 1987), which resulted in ptosis on the denervated side (Figure S4A) as seen in the Horner’s syndrome (Walton and Buono, 2003). Denervation was confirmed by whole-mount immunofluorescence staining for the sympathetic nerve marker tyrosine hydroxylase (TH) (Zhou et al., 1995), which revealed marked reductions in the number of TH+ fibers in the neurectomized sides of the tissues compared to the sham-operated contralateral sides (Figure 4A–B). Thus, these approaches allowed us to investigate the role of local innervation in nerve-intact and denervated tissues of the same mouse.
While brightfield intravital microscopy (BIM) studies of the cremasteric microvasculature revealed no circadian oscillations in leukocyte rolling (Figure 4C), leukocyte adhesion (Figure 4D) and extravasation (Figure 4E) were significantly elevated at night in contralateral muscle tissues with no oscillations observed in the denervated side. In addition, GFNx completely abolished the nightly increase in ICAM-1 expression (Figure S4B), suggesting that the night surge in ICAM-1 is controlled locally by adrenergic sympathetic nerve fibers. Adoptively transferred BM cells in SCGx animals exhibited circadian fluctuations in the numbers of adherent cells in the nerve-intact side, whereas the denervated side did not show any oscillations (Figure 4F). No circadian differences were observed in hemodynamic parameters, tissue weight or vascular density in neurectomized animals (Figure S4C–E and Table S2). Together, these studies demonstrate the importance of local innervation for circadian oscillations in hematopoietic cell recruitment to both skeletal muscle and BM.
Signals from the SNS are transmitted from the brain to peripheral tissues by norepinephrine through adrenoreceptors (Elenkov et al., 2000). To examine which adrenergic receptors were important for the circadian regulation of hematopoietic cell trafficking, we adoptively transferred fluorescently labeled WT BM cells into β2-(Adrb2) or β3-(Adrb3) adrenergic receptor-deficient recipients. We found that circadian oscillations in cell recruitment to the BM were significantly reduced in both recipient strains (Figure 4G–H). In addition, circadian differences in the expression of BM endothelial cell adhesion molecules were ablated in these mice (Figure S4F–G). Similarly, no circadian oscillations were observed in numbers of extravascular leukocytes in the cremaster muscle of Adrb2−/− or Adrb3−/− animals at steady state (Figure S4H–I) and BM chimeras for both strains revealed the critical role of non-hematopoietic β2- and β3-adrenoreceptors in circadian leukocyte recruitment to this tissue (Figure S4J–L). Furthermore, the night surge in ICAM-1 expression was averted when mice were treated with the β3-adrenoreceptor specific antagonist SR59230A (Figure S4M). These data clearly indicate that the endothelial oscillations in adhesion molecule expression require local delivery of adrenaline and signaling through β-adrenoreceptors
We next examined whether the circadian regulation of hematopoietic cell recruitment to the BM could be exploited in the setting of BM transplantation. Injection of lethally irradiated mice with limiting numbers of BM cells (25,000 cells), led to marked differences in survival. While most animals transplanted in the morning succumbed to death due to hematopoietic failure (Figure S5A), all animals survived the procedure when transplanted at ZT13 (Figure 5A–B). To test whether mimicking enhanced adrenergic tone at night could emulate this phenotype, we treated mice with the pan-β-adrenergic receptor agonist isoproterenol, which significantly upregulated expression of P- and E-selectins and VCAM-1 but not ICAM-1 in irradiated recipients (Figure 5C). After isoproterenol treatment, the number of recruited donor BM cells and progenitors was significantly increased compared to control (Figure 5D–E), while this effect was abrogated in Selp−/−Sele−/− or anti-VCAM-1-treated animals (Figure 5E–F). Furthermore, survival was markedly improved in the isoproterenol-treated animals when limiting numbers of BM cells were injected for transplantation (Figure S5B). To determine whether this effect was dependent on Adrβ2 or Adrβ3, we treated mice with specific agonists (clenbuterol or BRL37344, respectively). We found that only BRL37344 exhibited a similar effect as isoproterenol (Figure 5G, S5A and data not shown), indicating that β3-adrenergic receptor signaling is sufficient to promote hematopoietic recruitment to the BM. BRL37344 treatment also enhanced the homing of long-term repopulating hematopoietic stem cells (LT-HSC) (Figure 5H). Since we performed bone marrow transplantation 24hr after treatment with isoproterenol or BRL37344, the enhanced recruitment was likely due an effect on the stroma, rather than on the infused BM cells. We found no differences in CXCL12 levels between groups at the time of BMT (Figure S5C–D). These data suggested that transplantation performed at night or after pharmacological treatment with β3-agonists could potentially reduce the number of HSPCs needed for successful long-term engraftment.
Circadian rhythms are entrained by light where photic input is interpreted by suprachiasmatic nuclei (SCN), the fundamental timekeeper of the mammalian clock (Klein et al., 1991; Ralph et al., 1990). We thus tested whether alterations in photic input by induction of an experimental jetlag would be sufficient to modify rhythms in leukocyte recruitment. Advancing the light regime by 12h after the light phase (Figure 6A) completely abolished circadian rhythms in leukocyte recruitment to skeletal muscle (Figure 6B), and the oscillations in endothelial ICAM-1 expression (Figure 6C). Experimental jetlag also eliminated the increased homing to the BM at night (Figure 6D). To assess further the role of the molecular clock in the circadian fluctuations of leukocytes, we evaluated the role of BMAL-1, a key transcription factor required to entrain circadian oscillations (Levi and Schibler, 2007). We found that circadian oscillations of leukocyte numbers in both blood and tissues were completely abolished in Bmal1−/− animals kept in constant darkness for three weeks, in contrast to normal oscillations observed in heterozygous and WT littermates (Figure 6E–G). These results underscore the importance of light as an environmental cue required for synchronizing the clock machinery that entrains rhythms in leukocyte recruitment to tissues.
To assess whether circadian leukocyte recruitment could alter the inflammatory response, we injected mice with TNF-α and analyzed cremaster muscle tissues 8h later, either at ZT5 or ZT13. While leukocyte rhythms in blood were significantly blunted after stimulation (Figure 6I, left), neutrophil infiltration showed a dramatic increase compared to PBS treated animals (Figure 6H, left and and6J,6J, left). Circadian rhythms in leukocyte recruitment remained intact in inflammation, with ZT13 showing significantly higher neutrophil infiltration than ZT5 (Figure 6H, left and and6J,6J, left). In addition, ICAM-1 expression on endothelial cells was significantly increased after TNF-α-stimulation and exhibited circadian oscillations (Figure 6K, left). We also observed induction of endothelial cell adhesion molecule expression (P- and E-selectin, VCAM-1 and Cd44) as well as chemokines (Ccl2, Ccl5, Cxcl1, Cxcl2) after TNF-α-stimulation (Figure S6A–H), but no detectable rhythm. Icam2, Ccl3 or Cx3cl1 levels were not altered after inflammation and did not exhibit oscillations (Figure S6I–K).
When we induced jetlag and treated mice with TNF-α using the same protocol, circadian rhythms in WBC counts were inhibited (Figure 6I, right) and neutrophil infiltration was almost completely abolished (Figure 6H, right and and6J,6J, right) while the expression of endothelial cell adhesion molecules was dramatically reduced compared to controls kept under a normal light regime (Figure 6K, right and S6A–C). These experiments further illustrate the significance of circadian time and light in leukocyte recruitment under both steady-state and inflammatory conditions.
We next aimed to evaluate the relevance of circadian leukocyte recruitment in inflammation in models of sickle cell disease (SCD) and septic shock, pathologies in which neutrophil recruitment has been shown to play a critical role (Frenette and Atweh, 2007; Hewett et al., 1992; Thomas et al., 1992). SCD mice challenged with a TNF-α-induced model of vaso-occlusion (Figure S7A) exhibited significantly increased leukocyte recruitment to the cremaster muscle when the experiment was performed at night compared to the daytime (Figure S7B–C). In addition, adherent leukocytes showed marked elevations in Mac-1 integrin activation at night (Figure S7D), a key molecule mediating heterotypic interactions between activated adherent leukocytes and circulating RBCs (Hidalgo et al., 2009). This translated to a ~2-fold increase in WBC-RBC interactions (Figure S7E) and a significant decrease of the mean venular blood flow rates (Figure S7F). Ultimately, the overall survival of SCD mice was significantly reduced at night. Lethality was due to disseminated intravascular coagulation as evidenced by microthrombi in the lungs as well as scattered foci of liver necrosis (Figure S7G–I and data not shown). Importantly, we did not observe circadian differences in TNF-receptor expression at the investigated time points (Figure S7J). These data indicate that circadian leukocyte recruitment can exacerbate sickle cell vaso-occlusion and compromise survival.
To gain further insight into the relevance of circadian leukocyte recruitment to vital organs, we performed adoptive transfer studies using BM harvested from Vav1-Cre; Rosa26-lsl-Luc mice, expressing luciferase selectively in hematopoietic cells. Consistent with our studies in the muscle and bone marrow, we observed strong recruitment of adoptively transferred cells to the liver with a circadian rhythm peaking at night (Figure 7A). These rhythms coincided with oscillations in endothelial ICAM-1 and VCAM-1 expression (Figure 7B) whereas expression of endothelial selectins was unchanged (data not shown). To test further the relevance of these fluctuations, we challenged mice with a lethal dose of endotoxin (LPS) in the morning or at night. Consistent with our results with TNFα, both adhesion molecule expression (Figure 7C) and leukocyte recruitment exhibited strong oscillations, with neutrophil infiltration into liver peaking when LPS was administered at night (Figure 7D–F). In contrast, diurnal variations in neutrophil recruitment to this tissue were ablated in Icam1−/− animals (Figure 7D–F). Similarly to TNF-receptor expression, we also did not observe circadian rhythms of TLR4 (the principal receptor for LPS) at these timepoints (not shown). In line with prior studies (Feigin et al., 1969; Halberg et al., 1960), survival was greatly reduced when mice were challenged with LPS in the night compared to the morning (Figure 7G). Mortality was highly dependent on leukocyte recruitment since Icam1−/− animals were significantly more resistant to LPS-induced lethality (Xu et al., 1994) (Figure 7H). Additionally, the impaired survival of night-challenged animals was abrogated in Icam1−/− mice, indicating that oscillating ICAM-1 levels are critical for the observed diurnal rhythm (Figure 7H). Icam+/− animals exhibited an intermediate phenotype in survival compared to WT and Icam1−/− mice indicating the functional importance of differences in ICAM-1 expression observed in this model (Figure S7K). Taken together, these results demonstrate that circadian rhythms in leukocyte recruitment can directly impact the outcome of inflammatory diseases.
Here, we show that the emigration of leukocytes to tissues is regulated by signals from the autonomic nervous system where the peak recruitment occurs at night in rodents, during a period of activity. Circadian hematopoietic cell recruitment is synchronized by the molecular clock via sympathetic nerves, which induce through β-adrenoreceptors oscillations in endothelial cell expression of ICAM-1 and CCL2 in skeletal muscle and endothelial selectins, VCAM-1 as well as CXCL12 (Mendez-Ferrer et al., 2008) in the BM. In addition, our data suggest that rhythmic leukocyte recruitment is not restricted to these tissues but occurs in many vital organs. The difference in the molecular signature of circadian expression of endothelial cell adhesion molecules and chemokines in tissues is likely responsible for the diurnal preference in hematopoietic cell populations recruited to various organs.
Changes in the light cycle, a major zeitgeber for circadian rhythms (Golombek and Rosenstein, 2010), were sufficient to ablate oscillations in hematopoietic cell recruitment. This finding, along with the involvement of BMAL-1, strongly indicates bona fide circadian rhythms and suggests their central orchestration by the molecular clock (Dibner et al., 2010; Green et al., 2008). Additionally, the surprising anti-inflammatory effect seen after acute jetlag suggests a potent and broad interference of light in the normally rhythmically generated inflammatory response. It is possible that chronic jetlag may perturb circadian immune-surveillance mechanisms and contribute to the higher incidence of cancer in shift workers (Filipski et al., 2004). How jetlag exerts these broad changes in the inflammatory response should be the subject of future investigations.
Most prior studies on the regulation of circadian rhythms have focused on the involvement of humoral factors, notably of glucocorticoid (GC) levels, which peak at night in mice and reach trough values during the day (Dickmeis, 2009). Since GCs exhibit anti-inflammatory properties, we would expect that GC hormones might antagonize the rhythms described herein which depend on local innervation. It is possible however, that neural and hormonal pathways complement each other to fine tune the physiological and inflammatory responses (Elenkov et al., 2000). Thus, higher levels of GCs at night in mice may in fact keep the night surge in leukocyte infiltration in check.
Although catecholamine treatment of donor progenitors in vitro enhanced their engraftment ability through the β2-adrenoreceptor (Spiegel et al., 2007), we have excluded a role for adrenergic receptors on transplantable hematopoietic cells in our studies using radiation chimeras and adoptive transfer experiments. Therefore, endothelial cells in BM and skeletal muscle, which can express both the β2- and β3-receptors (Steinle et al., 2003), likely represent a logical cellular target since they also express the necessary adhesion molecules to mediate hematopoietic cell/endothelial cell interactions. Our results indicate that BM transplantation performed after stimulation with β3-adrenergic agonists in the recipient may improve clinical outcomes through enhanced engraftment efficiency. Since adrenergic stimulation can also induce the mobilization of HSPCs (Mendez-Ferrer et al., 2008), it remains unclear as to how the cells targeted by adrenergic signals interpret these signals at different times. The fact that the same adrenergic receptors can lead to distinct adhesion molecule expression in different vascular beds, suggests tissue-specific signaling responses that remain undefined. The present findings are consistent with previous studies in which circadian oscillations of BM CXCL12 with trough expression levels of the chemokine occurring in the morning were associated with the peak of HSC egress (Mendez-Ferrer et al., 2008). It is likely that the nightly increase of CXCL12 in the BM cooperates with endothelial upregulation of adhesion molecules for maximal hematopoietic cell homing in the evening. In the bone marrow, β3-adrenoreceptor expression is enriched in rare Nestin+ perivascular mesenchymal stem cells, which express high amounts of CXCL12 and are targeted by the SNS in the stem cell niche (Mendez-Ferrer et al., 2010). How microvascular pericytes collaborate with endothelial cells to entrain rhythms in extramedullary tissues will be the subject of future studies in the laboratory.
The rhythmic pattern of leukocyte recruitment may have evolved for the benefit of having readily available tissue phagocytes to enhance the response to pathogens during the period of activity, when injuries and encounters with microorganisms are more likely to occur. Although macrophages represent the major leukocyte subset oscillating under homeostasis, we show that neutrophil recruitment after trauma or in the setting of inflammatory diseases is significantly influenced by endogenous rhythms of endothelial cell adhesion. It is conceivable that the diurnal clearance of senescent neutrophils by the BM and liver is mediated by these circadian mechanisms. Whether the HSPC pool is rejuvenated by diurnal migratory incentives is possible. We have presented clear evidence, however, that circadian timing can influence the engraftment efficiency when HSPC counts are sub-optimal, demonstrating the significance of circadian hematopoietic cell recruitment to the BM. As such, given the inverted rhythms between rodents and humans (Lucas et al., 2008), we would predict that human hematopoietic stem cell transplantation is optimal early in the morning, rather than later in the day.
We postulate that the diurnal mechanisms of keeping neutrophil numbers in check may affect cardiovascular diseases – which are influenced by circadian time – as their levels are known to correlate positively with the degree of severity (Coller, 2005; Muller et al., 1985). When exaggerated, these mechanisms may exert detrimental effects. Indeed, in models of TNF-α-induced vaso-occlusion in SCD mice and LPS-induced lethality, we have found that circadian rhythms modulate the robustness of the inflammatory response with implications on survival. While we recognize potential mechanistic differences between atherosclerosis and inflammatory models studied herein, these data are in line with prior studies that have shown persistent oscillations in the susceptibility of mice to bacterial infection and inflammatory leukocyte trafficking (Castanon-Cervantes et al., 2010; Feigin et al., 1969; Gibbs et al., 2011; Halberg et al., 1960; House et al., 1997; Keller et al., 2009; Liu et al., 2006; Shackelford and Feigin, 1973; Silver et al., 2012). Sensitivity to inflammatory stimuli at times of higher SNS tone likely interacts at multiple levels encompassing local neural input as we describe herein, endogenous rhythms within tissues as well as interactions with humoral factors and the parasympathetic nervous system.
Given the reported critical role of blood leukocytes in ischemic vascular diseases, the present results argue that circadian leukocyte adhesion or an exaggeration thereof might contribute to triggering acute vascular diseases in the morning. Our own as well as published studies have clearly shown that leukocyte recruitment promotes LPS-induced lethality (Xu et al., 1994) and SCD vaso-occlusion (Hidalgo et al., 2009; Turhan et al., 2002), which led us to evaluate experimentally the effect of circadian time in inflammatory diseases. Our results provide the proof-of-principle that time-dependent differences in leukocyte recruitment translate into significant changes in survival. Thus, a better understanding of rhythms in leukocyte migration will allow the design of targeted chronotherapy that may lead to meaningful clinical impact on disease outcome.
We thank Dr. Rani Sellers for histopathological examinations, Dr. Lydia Tesfa for cell sorting experiments and Colette Prophete, Matt Huggins and Neepa Dholakia for technical assistance. This work was supported by the National Institutes of Health (NIH) (R01 grants HL097700; HL069438; DK056638) to P.S.F. We are grateful for fellowship support from the German Academic Exchange Service (DAAD) to C.S, the Japan Society for the Promotion of Science (Y.K.), the Fundación Ramón Areces (D.L.), a Ruth L. Kirschstein National Research Service Award from NHLBI (F30HL099028) to A.C. and a Founders Affiliate Predoctoral Fellowship from the American Heart Association (J-E.J.).
Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.